DE69910847T2 - NESTED MULTI-BAND GROUP ANTENNAS - Google Patents

Abstract

Antenna arrays which can work simultaneously in various frequency bands thanks to the physical disposition of the elements which constitute them, and also the multiband behaviour of some elements situated strategically in the array. The configuration of the array is described based on the juxtaposition or interleaving of various conventional mono-band arrays working in the different bands of interest. In those positions in which elements of different multiband arrays come together, a multiband antenna is employed which covers the different working frequency bands. The advantages with respect to the classic configuration of using one array for each frequency band are: saving in cost of the global radiating system and its installation (one array replaces several), and its size and visual and environmental impact are reduced in the case of base stations and repeater stations for communication systems. <IMAGE>

Description

OBJECT THE INVENTION

The present invention exists from arrangements of antennas due to a physical arrangement the elements of which they are made and the multi-band behavior some elements that are strategically placed in the array, can work on different frequencies at the same time.

The composition of the arrangement is based on a juxtaposition or coupling of several conventional Single band orders described on the targeted frequency work. At the positions where elements of different multi-band arrangements converge, a multi-band antenna is used, the different Covers working frequencies.

The use of a multi-band arrangement from Interlaced antennas (hereinafter only interlaced multi-band arrangement AEM) means a big advantage over the conventional ones Solutions, where an arrangement for any frequency is used: there will be costs in the global broadcasting system and saved on installation (one arrangement replaces several), the size and the optical and ecological Impact in the case of base stations and amplifiers from Communication systems degraded.

The present invention takes place Application in the field of telecommunications and more specifically in systems of radio communication.

PREVIOUS TECHNOLOGY AND OVERVIEW OF INVENTION

Antennas were started at the end of the last century to develop after James C. Maxwell 1864 the basic laws of the Electromagnetism postulated. Heinrich Hertz invented it in 1886 attributed to the first antenna used to transmit of electromagnetic waves through the air. Middle of 1940s became the basic limitations of antennas reducing their size compared to the length proved the wave and at the beginning of the sixties the first frequency independent Antennas on (E.C. Jordan, G.A. Deschamps, J.D. Dyson, P.E. Mayes, "Developments in broadband antennas ", IEEE Spectrum, volume 1, pages 58-71, Apr 1964; V. H. Rumsey, "Frequency-Independent Antennas ", New York Academic, 1966; R.L. Carrel, "Analysis and design of the log-periodic dipole array ", Tech. Rep. 52, University of Illinois Antenna Lab., Contract AF33 (616) -6079, Oct 1961; P.E. Mayes, "Frequency Independent antennas and broad band Derivatives Thereof ", Proc. IEEE, Volume 80, No. 1, Jan. 1992.) At that time, propellers, logoperiodic arrangements, cones and exclusively from angles existing structures for execution proposed by broadband antennas.

The theory of antenna arrangements goes back to the work of Shelkunoff (S. A. Schellkunhoff, "A Mathematical Theory of Linear Arrays, "Bell System Technical Journal, 22, 80) and other classic treatises of antenna theory. Said theory specifies the rules of the basic concept, to achieve the radiation properties of the arrangement (mainly its Broadcasting diagram), although the application is mainly based on limited the case of single band arrangements. The reason for this limitation is that the frequency behavior of the arrangement largely depends on the ratio between the distance between the elements (antennas) of the arrangement and the length depends on the working wave. This The distance separating the elements is usually the same and is preferred less than one wavelength, to prevent the appearance of diffraction overlaps. This entails that when determining the distance between the working frequency (and the associated wavelength) are determined at the same time , it is particularly difficult that the same arrangement works on another, higher frequency at the same time, because in this case the wavelength is lower is the distance between the elements.

The logoperiodic arrangements represent one of the first examples of antenna arrangements, that are able to cover a wide frequency range (V. H. Rumsey, Frequency-Independent Antennas, New York Academic, 1966; R.L. Carrel, "Analysis and design of the log-periodic dipole array ", Tech. Rep. 52, Univ. Illinois Antenna Lab., Contract AF33 (616) - 6079, Oct 1961; P.E. Mayes, "Frequency Independent Antennas and Broad-Band Derivatives Thereof ", Proc. IEEE, Band 80, No. 1, Jan. 1992). Said orders are based on the distribution of the elements that make it up, so the distance between neighboring elements and their length vary depending on the geometric sequence changed. Although said antennas are able to transmit the same and maintain impedance diagram in a wide frequency range, is the practical application due to its limitations in terms of reinforcement and size in specific cases limited. So the said antennas are not, for example, in base stations used in mobile communications because they do not have sufficient amplification (their amplification lies in the range of 10 dBi, being for this Application normally around 17 dBi are necessary), they are linear Have polarization while with said application antennas with different polarizations needed your horizontal diagram does not have the necessary width and their mechanical structure is too big.

The technology of individual multi-band antennas, on the other hand, are much more advanced. A multi-band antenna is an antenna that consists of an arrangement of electromagnetically connected elements that work collectively and collectively in order to achieve the radio-electric behavior of the antenna the multi-band antenna). Many examples of multi-band antennas are described in the literature. In 1995, fractal or multi-fractal antennas were introduced (BB Mandelbrot in his book "The Fractal Geometry of Nature", WH Freeman et al. 1983 is the coining of the terms fractal and multi-fractal attributable), which are antennas that are due to their geometry exhibited multifrequency behavior and in certain cases a reduced size (C. Puente, R. Pous, J. Romeu, X. Garcia "Antenas Fractales o Multifractales", (Spanish patent ES 2112163)). Later, the multi-triangular antennas were introduced (Spanish patent ES 2142280), which operate simultaneously on the GSM bands 900 and 1800 and later the multi-stage antennas (document WO-A-0122528), which are a clear example of how the geometry of the antenna is designed to achieve multi-band behavior.

Document WO-A-9735360 claims one dual band arrangement that works on the L band and UHF band. The Arrangement comprises a main unit with a stacked switching element that works on the UHF band and a variety of cross dipoles that form an L-band ring arrangement which is placed on the UHF element.

The present invention describes how multi-band antennas can be combined to form an array achieve that works simultaneously on different frequency bands.

An interlaced multi-band arrangement (AEM) consists of an arrangement of antennas that have the special feature that they are able to simultaneously on different band frequencies work. This is achieved by using multi-band antennas in strategic Positions of the arrangement used. The arrangement of the elements, which make up the AEM is made by juxtaposition of conventional ones Single band arrangements achieved, with so many single band arrangements are used like frequency bands to be included in the interlaced multi-band arrangement. For positions where one or more elements from the usual Single band arrangements are the same, becomes a single multi-band antenna (Element) that simultaneously covers the different tapes. With the other mismatched ones Positions, the same multi-band antenna can also be used, that works on the appropriate frequency. The suggestion of a or multiple frequencies of each element of the array depends from the position of the element in the array and is indicated by controls the signal distributor.

SHORT DESCRIPTION THE DRAWINGS

The described properties of the previously presented are graphically represented by the figures of the drawings of the appendix, in which as purely illustrative and not restrictive Examples of preferred execution explained becomes. In these drawings:

The 1 the position of the elements of the conventional single band arrangements, each operating on the frequency f and f / 2, and the position of the elements in an interlaced multi-band arrangement, which has a dual behavior at the frequency (at the frequencies f and f / 2), while equally works like the conventional arrangements but with a smaller number of elements.

The 2 another separate example of an interlaced multi-band arrangement, but in this case with three frequencies, and the respective three conventional single-band arrangements from which they are composed. It is an extension of the case of 1 on 3 Frequencies f, f / 2, f / 4.

The 3 another separate example of an interlaced multi-band arrangement in which the different operating frequencies are not separated by the same scale factor. It is an extension of the cases of 1 and 2 on 3 frequencies f, f / 2 and f / 3.

The 4 another separate example of an interlaced multi-band arrangement in which the different operating frequencies are not separated by the same scale factor. It is an extension of the case of 3 on 3 frequencies f, f / 3, f / 4.

The 5 an embodiment of an interlaced multi-band arrangement, which requires a different structuring of the elements in order to achieve frequencies which do not correspond to a whole divider of the higher frequency. In this example, the frequencies f, f / 2 and f / 2.33 were chosen.

The 6 an extension of the design of an AEM to a two- or three-dimensional case, specifically, an extension of the example of the 1 on two dimensions.

The 7 a preferred working mode (AEM1). It is an AEM arrangement in which the multi-band elements are multi-triangular elements. The arrangement works simultaneously on double frequencies, for example on the bands GSM 900 and GSM 1800.

The 8th another preferred working mode (AEM2).

It is an arrangement AEM, in which the multi-band elements are multi-stage elements. The order works simultaneously on double frequencies, for example the band GSM 900 and GSM 1800.

The 9 another preferred working mode (AEM3). It is an AEM arrangement in which the multi-band elements are multi-stage elements. The design is similar to that of 8th (Operation AEM2) with the difference that the new design makes it possible to reduce the overall width of the antenna.

The 10 another example of a multi-band antenna that can be used with the AEM. It is an antenna with stacked switching elements, which in this case works on double frequencies (for example GSM 900 and GSM 1800).

The 11 the design of said switching elements in the arrangement of the type AEM (arrangement AEM4). It should be noted that in contrast to the other cases, in this case multi-band antennas are only used in those positions where it is really necessary; on the other single-band elements are used, the transmission diagram of which is sufficiently similar to the multi-band elements of the corresponding band.

The 12 another arrangement (AEM5) in which the elements have been rotated 45 ° to obtain double polarization at + 45 ° or -45 °.

DESCRIPTION THE PREFERRED VERSION THE INVENTION

For the detailed description that follows from the preferred execution is made, is constantly Reference is made to the figures of the drawings by which the same Numbers for same or similar Parts are used.

An interlaced multi-band arrangement (AEM) is achieved by juxtaposition of various conventional single-band arrangements achieved. The arrangements more conventional Antennas usually have a single band behavior (that is, they operate in a relatively small frequency range, typically around 10% around a main frequency) and that's not just because that the elements (antennas) that make them up have a single band behavior have, but also that the distance between the elements the length due to the working wave. Typically the conventional ones Single band arrangements designed with a space between the elements, which is about half a wavelength, this distance increased in some arrangements can be used to increase directivity, though normally lower than a wavelength is held to prevent the emergence of diffraction overlaps.

This purely geometric limitation (the size of the wavelength determines the geometry of the elements of the arrangement and their relative spacing) represented a major disadvantage in the communication systems and areas in which several frequency bands have to be used at the same time. A clear example of this is the GSM mobile radio system. Initially, the GSM was on the 900 MHz band, but has since developed into one of the most widespread in the world. The success of the system and the spectacular growth in demand for this type of service have led the mobile phone companies to extend their services to a new band, the 1800 MHz band, to cover a larger number of customers. When using conventional single-band antenna technology, companies must double the antenna network to cover the GSM 900 and the GSM 1800 at the same time. If a single AEM arrangement specifically designed for the system (as in the special cases of 7 to 12 ), the telephone operators reduce the costs for the network of base stations, the expansion time on the new band and the optical and ecological effects of their facilities (by simplifying the global broadcasting structure).

It is important to emphasize that the situation described is just a specific example of a species of AEM and its application; any specialist in the field will understand that the AEM arrangements described in the present Invention are described, by no means specific to this Design limited and can be easily adapted to other frequencies and applications can.

The interlace multi-band orders their operation is based on the arrangement of the antennas which they are composed of and on the special kind of element, that used in some strategic positions of the arrangement becomes.

The positions of the elements in a AEM are in so many single-band arrangements due to the positions of the elements defines how frequencies or frequency bands are required. The conception in this respect the arrangement is the same as that of the single band arrangements, insofar as the current weight of each element is chosen can make the broadcast diagram according to the requirements of each Achieve application. The design of the AEM is by the Juxtaposition of the positions of the various single band arrangements achieved. The juxtaposition is of course practically very difficult to perform at the positions on which different antennas of different arrangements meet; the solution proposed by this invention lies in the application of a multi-band antenna (for example fractal, multi-triangle, multi-stage antennas), the covers all frequencies assigned to the position.

A basic and special example, How to arrange the elements of an AEM is described in the 1 described. In the columns of Figures (1.1) and (1.2) two conventional single-band arrangements are shown, in which the positions of the elements (each marked by the black circles and circumferences) are selected such that the distance between the elements is typically less than the length the working wave. Taking the working frequency f of the arrangement (1.1) as a reference, the arrangement (1.2) would work at a frequency f / 2, since the elements double their distance in relation to the previous case. In the figure (1.3) the arrangement of the elements of the AEM is described, which is able to work simultaneously on the frequencies f and f / 2, whereby it basically provides the same services as the two arrangements (1.1) and (1.2 ). At the positions where elements of the two conventional arrangements meet (indicated by black circles in the middle of a circumference in the figure (1.3)), a multi-band antenna is used which works in the same way on the frequencies (1.1) and (1.2) can work (same impedance and same diagram). The remaining elements that are not common (identified either by a black circle or a perimeter) can be implemented either by the same multi-band element used for the common elements (the working frequency being selected by the signal distributor of the arrangement) or by the use of conventional single band elements. In this example, arrangement (1.3) has a dual behavior on frequency (on frequencies f and f / 2) and works in the same way as arrangements (1.1) and (1.2), but with a lower total number of elements (12 instead of 16).

It is in the state of the art described many examples of multi-band antennas. The antennas with fractal geometry, the multi-triangular antennas, the multi-layer antennas and even those with stacked switching elements are some examples for antennas, who are able to do similar things in many frequency bands to work. These and other multi-band antennas can be in the positions of the AEM are used in which elements of different single band arrangements converge.

In the following figures, other configurations of the AEM are described, which are based on the same essence of the invention, even if the arrangement of the elements is adapted to other frequencies. In the 2 will describe the arrangement of a three-band AEM that operates on the frequencies f, f / 2 and f / 4. The arrangement of the elements of the three conventional single-band arrangements on the frequencies f, f / 2 and f / 4 is shown in Figures (2.1), (2.2) and (2.3) by black circles, perimeters and squares. The position of the elements of the AEM is determined by the design of the three single band arrangements, which are each designed for the three frequencies. The three arrangements converge in the AEM, which is shown in Figure (2.4). A multi-band element is used at the positions at which elements of the three arrangements would converge (represented in the drawing by the comparison of the different geometric figures which characterize each arrangement). The arrangement with three frequencies of Figure (2.4) behaves exactly like the three arrangements (2.1), (2.2) and (2.3) at their respective operating frequencies, but using only 13 elements instead of the 21 necessary for the three single-band arrangements are.

The 3 . 4 and 5 describe the structure of the other AEMs, which are based on the same principle but on different frequencies, by way of example and not by way of limitation. In the first two cases, the frequencies used are whole multiples of a basic frequency; in the case of 5 The relationship between the frequencies is not restricted to any particular rule, although it represents an example of an arrangement in which the frequencies of the services GSM 900, GSM 1800 and UMTS can be combined.

This concretely illustrates 3 another separate example of the interlaced multi-band arrangement, in which the different operating frequencies are not separated by the same scale factor. It is an extension of the case of 1 and 2 at 3 frequencies f, f / 2 and f / 3. The arrangement of the elements of the three conventional single-band arrangements on the frequencies f, f / 2 and f / 3 are shown in FIGS. (3.1), (3.2) and (3.3) by black circles, perimeters and squares. The column in Figure (3.4) shows the arrangement of the elements in the interlaced three-band arrangement. A multi-band element is used at the positions at which elements of the three arrangements converge (represented in the drawing by the comparison of the different geometric figures which characterize each arrangement); the same strategy is followed at the positions where elements of two arrangements converge: a multi-band element must be used that is capable of covering all of its own frequencies in its position, preferably the same element that is used on the other positions, the frequencies that are necessary are selected by means of an excitation network. It should be noted that the arrangement with three frequencies of Figure (3.4) behaves exactly like the three arrangements (3.1), (3.2) and (3.3) on their respective working frequencies, but only 12 elements are used instead of the 21 which are necessary in total for the three single-band arrangements.

The 4 describes a new example of an interlaced multi-band arrangement in which the different operating frequencies are not determined by the same scale factor are separated. It is an extension of the case of 3 on 3 frequencies f, f / 3 and f / 4. The arrangement of the elements of the three conventional single-band arrangements on the frequencies f, f / 3 and f / 4 are shown in FIGS. (4.1), (4.2) and (4.3) by black circles, perimeters and squares. The column in Figure (4.4) shows the arrangement of the elements in the interlaced three-band arrangement. A multi-band element is used at the positions at which elements of the three arrangements converge (represented in the drawing by the comparison of the different geometric figures which characterize each arrangement). It should be noted that the arrangement with three frequencies of Figure (4.4) behaves exactly like the three arrangements (4.1), (4.2) and (4.3) on their respective working frequencies, but only 15 elements are used instead of the 24, which are necessary in total for the three single-band arrangements.

It is appropriate to emphasize that in special cases the 3 and 4 the arrangements can work on 3 frequencies simultaneously. The arrangement of the elements is such that the three frequencies do not always match in all elements, nevertheless the AEM can be created by using a three-band antenna in these positions and selecting the working frequencies, for example by means of an election network on a conventional frequency.

In some configurations of interlaced multi-band arrangements, particularly those in which the different frequencies do not match an entire divisor of the main frequency 1, a new positioning of the elements is required, as in FIG 5 , In this separate example, the frequencies f, f / 2 and f / 2.33 were chosen. The arrangement of the elements of the three conventional multi-band arrangements on the frequencies f, f / 2 and f / 2.33 are represented in FIGS. (5.1), (5.2) and (5.3) by black circles, perimeters and squares. The column of Figure (5.4) shows the arrangement of the elements in the interlaced three-band arrangement according to the same scheme of the previous example. It should be noted that in this case the ratio of the frequencies requires an arrangement of the elements in intermediate positions, which makes practical application difficult. The solution in this case is to change the position of the element of the arrangement operating on the lowest frequency (indicated by arrows) so that it matches another element (the one closest to it) of the arrangement located on the highest frequency works. Then the two elements that occupy the same position are replaced by a multi-band element. An example of the final arrangement after the elements have been repositioned is described in Figure (5.5). It is important that the shifted element is preferably the element of the lower frequency arrangement so that the relative shift in the length of the working wave is as small as possible and secondary or diffraction overlaps are avoided as much as possible.

The 6 illustrates that the design of the AEM arrangements is not limited to the linear case (one-dimensional), but also includes arrangements in 2 or 3 dimensions (2D and 3D). The procedure for distributing the elements of the arrangement in the case of 2D and 3D is the same, with the different matching elements also being replaced by a single multi-band antenna.

Following are more examples described by separate configurations of AEM arrangements. In the five The examples described are different designs for the systems GSM 900 and GSM 1800 (bands 890 MHz-960 MHz and 1710-1880 MHz) reproduced. These are antennas for base stations for the Cellular, the main one on both bands have the same electromagnetic behavior. By using it This type of AEM antenna reduces the number of providers installed antennas by half and lower costs and ecological Impact to a minimum.

AEM1 mode

The design AEM1, which in the 7 is based on the use of multi-triangular elements GSM 900 and GSM 1800. The arrangement is obtained by interlacing two conventional single-band arrangements with a distance between the lower elements which is less than a wavelength () on the corresponding band (typically a distance becomes selected to be less than 0.9 to reduce the occurrence of diffraction overlaps in the endfire direction). The output arrangements can consist of 8 or 10 elements, depending on the gain required by the operator. The juxtaposition of both arrangements in a single AEM arrangement is obtained in this case through the use of dual multi-triangle elements. These elements have two excitation points (one for each band), which allows the working band to be selected according to its position in the array. In the 7 the position of the elements and their working frequency is described. The elements shown in white indicate the functioning on the GSM 900 band; the elements shown in black indicate the functioning on the GSM 1800 band and the elements marked in black in the lower triangle and in white in the two upper triangles indicate the simultaneous functioning on both bands. It is this simultaneous work of both bands by a single multi-band element (the multi-triangle element) in these positions of the assembly (the positions where the original single-band assemblies match) is one of the main features of the AEM invention.

The type of supply for the elements of the AEM1 arrangement is not characteristic of the invention of the AEM and it can be any known conventional Scheme can be used. Specifically and because of the multi-triangular elements can be excited at two different points, an independent distribution network for each Tape can be used. Another option is to use it a broadband or double band distribution network, with a starting resistor / diplexor can be switched, the network and the two excitation points of the Multi-triangular antenna connects.

Finally, the antenna can too two connectors for the entrance and exit (one for each band) or in a connector by means of a starter resistor network / diplexor network be combined.

AEM2 MODE

This special design of the AEM2, which is in the 8th is shown, is based on a multi-layer antenna that functions as multi-band elements. It works simultaneously on the GSM 900 and GSM 1800 bands and also has double linear polarization at + 45 ° and –45 ° with respect to the longitudinal axis of the arrangement. The fact that the antenna has double polarization represents an additional advantage for the mobile radio operator, since in this way a diversity system can be implemented which minimizes the effect of the signal loss due to the reusable radiation. The multilayer element, which in the 8th is more appropriate than the previously described multi-triangle element, since the element itself has a linear polarization at + 45 ° for GSM 900 and at -45 ° for GSM 1800.

The arrangement is obtained by intertwining two conventional single band arrangements with a spacing between the lower elements that is less than a wavelength () on the corresponding band (typically a spacing less than 0.9 is chosen to avoid the occurrence of diffraction overlaps decrease in the endfire direction). The output arrangements can consist of 8 or 10 elements, depending on the gain required by the operator. The juxtaposition of both arrangements in a single AEM arrangement is obtained in this case through the use of dual multilayer elements. These elements have two excitation points (one for each band), which allows the working band to be selected according to its position in the array. In the 8th the position of the elements and their working frequency is described. The elements shown in white indicate the functioning on the GSM 900 band; the elements shown in black indicate the functioning on the GSM 1800 band and the elements marked in black in the lower triangle and in white in the two upper triangles indicate the simultaneous functioning on both bands. It is this simultaneous operation of both bands by a single multi-band element (the multi-triangular element) in these positions of the arrangement (the positions where the original single-band arrangements match) is one of the main features of the AEM invention.

One can double polarization by making the multilayer element at different Points of its surface energized; but to differentiate the insulation between the connectors Increasing polarization you choose in the example described the implementation of a double pillar Separation of the polarization at + 45 ° (left column) from that at - 45 ° (right column). to increase the insulation between the bands can also the polarization tendency of the columns of the arrangement in one Band (for example DCS) can be exchanged.

The type of supply for the elements of the AEM2 arrangement is not distinctive for the invention of the AEM and it can be any known conventional Scheme can be used. Specifically and because of the multi-triangular elements can be excited at two different points, an independent distribution network for each Tape can be used. Another option is to use it a broadband or double band distribution network, with a starting resistor / diplexor can be switched, the network and the two excitation points of the Multilayer antenna connects. So the antenna can either four connectors for the entrance and exit (one for each band and polarization) or in only two connectors (one for every independent Polarization) by means of a starting resistor network / diplexor network be combined.

AEM3 MODE

The design AEM3, which in the 9 is shown, the AEM2 is very similar (the position of the multi-elements and the nature of the elements themselves are the same as in the previous case) except for the fact that the right column is reversed with respect to the left column. In this way a double band antenna with polarization is obtained, the total width of the antenna being reduced compared to the previous case (in this special case the width is reduced by 10%). To increase the insulation between the columns with double polarization, it is advisable to place two sloping wings between adjacent columns bring. In this case, longitudinal wings are also attached to all the elements which work on GSM 1800 and which help to narrow the radiation beam on a horizontal plane (plane perpendicular to the longitudinal axis of the arrangement).

The signal distribution system is too not particularly characteristic of the design of the AEM, and it can use the same scheme as the previous one Case be applied.

AEM4 MODE

Another example of an interlaced multi-band arrangement is that which we have named AEM4 and is described in the 11 schematically. In this case, the multi-band element is an antenna with stacked square switches ( 10 ), although it is obvious to any person skilled in the art that switches with other shapes, square or round, can also be used if one wants to work with double polarization. In the example of the 10 the separate case of square switches is described.

The lower switch will be appropriate designed so that the resonance frequency (typically with the basic mode of the switch associated) with the lower band (in this concrete Case GSM 900) matches; this switch also functions as a ground plane for the upper switch is working. This last one is designed to resonate in the upper band (GSM 1800) is centered. The elements of the arrangement are built on a metallic or metallized surface. The supply system is preferably coaxial, with a Cable for the lower switch and the lower bands and another cable for the upper switch and the upper bands is used. The excitation points are on the bisector the switch is attached (as an example, the approximate excitation points marked with circles in the top view of the antenna) or on the diagonals if, on the contrary, a linear oblique polarization Reach 45 ° would like to. For the In case that desired is that the arrangement will work on double polarization additionally each switch at the opposite of the previous points Bisectors or diagonals (right-angled) excited.

The type of supply for the elements of the AEM4 arrangement is not distinctive for the invention of the AEM and it can be any known conventional Scheme can be used. Specifically and because the antenna is stacked with Switches energized at two different points can be an independent distribution network for each Tape can be used. Another option is to use it a broadband or double band distribution network, with a starting resistor / diplexor can be switched, the network and the two excitation points connecting the multi-layer antenna. So the antenna can either four connectors for the entrance and exit (one for each band and polarization) or in only two connectors (one for any independent Polarization) by means of a starting resistor network / diplexor network be combined.

AEM5 MODE

The design AEM5, which in the 12 is shown follows the same philosophy as AEM4, although all elements are rotated 45 ° to the antenna level. In this way, the radiation diagram is changed in the horizontal plane and the polarization is rotated by 45 °.

It is interesting to emphasize that both in the configuration AEM4 and in the AEM5 Multi-band element, which consists of stacked switches, only in the strategic positions is strictly necessary in which elements those from conventional Single band arrangements originate, match. In the other positions both Multi-band elements as well as single-band elements are used, the on the for their position fixed frequency work as long as their broadcasting diagram is similar enough to the antenna with stacked switches to overlap diffraction to avoid.

It is not considered necessary to make the content of this description more detailed so a specialist in the field the impact and benefits, which derive from the invention, understand and the subject of Developed invention and brings it to practical use.

However, it must be understood that the invention according to a preferred embodiment of the same described why it can be changed without this in any way changes their basis, these changes in particular the shape, size and / or manufacturing materials.

Claims (25)

Interlaced multiband directional radiator, which works simultaneously on several frequencies, the arrangement of the elements of the radiator resulting from the connection of as many individual band radiators as required operating frequencies, characterized in that in the positions in which two or more elements of the single band radiator match, a single one Multi-band antenna is used, which is able to cover the different working frequencies. Interlaced multiband directional emitter according to claim 1, wherein the single multi-band antenna is a fractal multi-band antenna is. Interlaced multiband directional emitter according to Claim 1, wherein the single multi-band antenna is a multi-stage multi-band antenna. Interlaced multiband directional emitter according to claim 1, wherein the single multi-band antenna is a multi-triangular multi-band antenna is. Interlaced multiband directional emitter according to claim 1, with the single multi-band antenna being arranged in stack memories formed from interconnect structures or microstrips become. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that the same fractals, multi-stage or multi-triangular multi-band antennas as on the normal Positions are applied when the elements are on a position two single band emitters do not match. Interlaced multiband directional emitter according to claim 6, characterized in that the working frequency of the fractal, multi-level or multi-triangle multi-band antennas in function with the Positions at the overlapping Multi-band radiators is selected by a frequency selection structure. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that when in one position the elements of two single-band radiators do not match, a single-band antenna is used, which works on the frequency that their position in the spotlight. Interlaced multiband directional emitter according to claim 8, characterized in that the single band element, which in the Positions are used in which no multi-band element is required is about has a radiation pattern, that of fractal, multi-level or multi-triangle multi-band antennas sufficiently resembles and has the same frequency, so with the pattern of the overlapping multi-band radiators the diffraction is reduced appropriately. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that the number of elements, their spatial Order in relation to the wavelength and also their current phase and current amplitude with all single band radiators, that are connected side by side are the same, so that the overlapping ones Multi-band emitters synthesized, so the same beam factors is achieved on the different tapes in question. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that the number of elements, their spatial Order in relation to the wavelength and also set their current phase and current amplitude on each frequency to match the radiation pattern in accordance with the individual needs of the communication system that works in each volume. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that the operated tapes around 900 MHz and 1800 MHz are arranged to simultaneously the cellphone systems GSM 900 and GSM 1800 to operate. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that the operated tapes around 1900 MHz and 3500 MHz are arranged to be the cordless at the same time and local radio access communication systems, such as to use those that use the DECT standard. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that the operated tapes around 900 MHz, around 1800 MHz and around 2100 MHz are arranged to run simultaneously to operate the GSM 900, GSM 1800 and UMTS mobile phone systems. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that the operated tapes around 800 MHz and 1900 MHz are arranged to simultaneously control the cellphone systems Use AMPS and PCS. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that a distribution network with single band signal for every working frequency and every single radiator is used which the spotlight is made of. Interlaced multi-band directional emitter according to claims 1, 2, 3, 4 and 5, characterized in that a single distribution network with multi-band signal is used to all elements of the radiator to turn on at all frequencies. Interlaced multiband directional emitter according to claim 16, characterized in that at the connections of the distribution network a frequency selection element is attached or integrated that a choice of elements that are turned on and at what frequency or frequencies. Interlaced multiband directional radiator according to Claims 1, 2, 3, 4 and 5, characterized in that the bands operated around 800 MHz, are arranged around 1900 MHz and around 2100 MHz in order to simultaneously operate the AMPS, PCS and UMT 2000 mobile phone systems. Interlaced multiband directional emitter according to claim 3 or 4, characterized in that the only multi-band antenna is switched on at two different points. Interlaced multiband directional emitter according to claim 5, characterized in that the side-by-side structures by 45 ° the plane of the antenna. Interlaced multiband directional emitter according to claim 1, characterized in that when different frequencies will not match an integral factor of the highest frequency some of the single band radiators operating on the lowest frequency work, realigned so that they can work with the next element of the single-band heater the highest Frequency match. Interlaced multiband directional emitter according to claim 1, characterized in that the single band emitter two or are three-dimensional spotlights. Interlaced multiband directional emitter according to claim 1, characterized in that the interlaced antenna has two columns of Includes elements, being a pillar for the + 45 ° polarization and the other pillar for the –45 ° polarization responsible is. Interlaced multiband directional emitter according to claim 24, characterized in that the elements of one of the columns are reversed are arranged compared to the elements of the other pillar.